Transcript Ionisation
Advanced Medicinal
Chemistry
Lectures 6 and 7:
Physical Properties and Drug
Design
Rhona Cox
AstraZeneca R&D Charnwood
Overview
Introduction
Ionisation
Lipophilicity
Hydrogen bonding
Molecular size
Rotatable bonds
Bulk physical properties
Lipinski Rule of Five
The Drug Design Conundrum
Two lectures
What must a drug do other than bind?
bladder
kidneys
BBB
bile
duct
liver
An oral drug must be able to:
dissolve
survive a range of pHs (1.5 to
8.0)
survive intestinal bacteria
cross membranes
survive liver metabolism
avoid active transport to bile
avoid excretion by kidneys
partition into target organ
avoid partition into undesired
places (e.g. brain, foetus)
Why are physical properties
important in medicinal chemistry?
So, before the drug reaches its active site, there are many hurdles
to overcome.
However, many complicated biological processes can be modelled
using simple physical chemistry models or properties – and
understanding these often drives both the lead optimisation and
lead identification phases of a drug discovery program forward.
This lecture will focus on oral therapy, but remember that there are
lots of other methods of administration e.g. intravenous, inhalation,
topical. These will have some of the same, and some different,
hurdles.
Reducing the complexity
Biological process in
drug action
Underlying physical
chemistry
Physical chemistry
model
Dissolution of drug in
gastrointestinal fluids
Energy of dissolution;
lipophilicity & crystal
packing
Solubility in buffer,
acid or base
Absorption from small
intestine
Diffusion rate, membrane
partition coefficient
logP, logD, polar
surface area, hydrogen
bond counts, MWt
Blood protein
binding
Binding affinity to blood
proteins e.g. albumin
Plasma protein binding,
logP and logD
Distribution of
compound in tissues
Binding affinity to cellular
membranes
logP, acid or base
Ionisation
Ionisation = protonation or deprotonation resulting in charged
molecules
About 85% of marketed drugs contain functional groups that are
ionised to some extent at physiological pH (pH 1.5 – 8).
The acidity or basicity of a compound plays a major role in controlling:
Absorption and transport to site of action
• Solubility, bioavailability, absorption and cell penetration, plasma
binding, volume of distribution
Binding of a compound at its site of action
• un-ionised form involved in hydrogen bonding
• ionised form influences strength of salt bridges or H-bonds
Elimination of compound
• Biliary and renal excretion
• CYP P450 metabolism
How does pH vary in the body?
Fluid
pH
Aqueous humour
7.2
Blood
7.4
Colon
5-8
Duodenum (fasting) 4.4-6.6
Duodenum (fed)
5.2-6.2
Saliva
6.4
Small intestine
6.5
Stomach (fasting)
1.4-2.1
Stomach (fed)
3-7
Sweat
5.4
Urine
5.5-7.0
So the same compound will
be ionised to different extents
in different parts of the body.
This means that, for example,
basic compounds will not be
so well absorbed in the
stomach than acidic
compounds since it is
generally the unionised form
of the drug which diffuses into
the blood stream.
Ionisation constants
The equilibrium between un-ionised and ionised forms
is defined by the acidity constant Ka or pKa = -log10 Ka
For an
acid:
Ka
For a
base:
H
HA
[H+][A-]
Ka =
[AH]
BH+
[H+][B]
Ka =
[BH+]
+
+
A
100
% ionised =
1 + 10(pKa - pH)
Ka
+
H
+
B
100
% ionised =
1 + 10(pH - pKa)
When an acid or base is 50% ionised:
pH = pKa
Ionisation of an acid – 2,4-dinitrophenol
100
OH
O
90
NO2
80
NO2
-H+
70
percent
60
% neutral
50
% anion
NO2
NO2
40
pKa = 4.1
30
20
10
0
3
4
5
6
7
pH
8
9
10
11
Ionisation of an base – 4-aminopyridine
NH2
-H+
100
90
+
N
80
N
H
70
percent
NH2
60
% neutral
50
% cation
40
30
20
10
0
3
4
5
6
7
pH
8
9
10
11
pKa = 9.1
Effect of ionisation on antibacterial potency
of sulphonamides
6.5
6
From pH 11 to 7
potency increases
since active species
is the anion.
5.5
potency
5
4.5
4
From pH 7 to 3
potency decreases
since only the neutral
form of the
compound can
transport into the cell.
3.5
3
2.5
2
2
3
4
O
O
S
R1
5
6
7
pKa
8
O
R2
N
H
9
O
S
R1
10
R2
N
-
11
Effects of substituents on ionisation
N
X
log(KX/KH) pyridines
Substituents have similar effects on the ionisation of different series of
compounds.
This is an
example of a
5
linear free energy
relationship.
3-NO2
3-CN
4
3
3-F
2
4-F
1
-0.2
-0.1
0
3-Me
-1
4-Cl
H
0
-0.3
3-Cl
0.1
0.2
0.3
0.4
0.5
0.6
log(KX/KH) benzoic acids
0.7
O
0.8
OH
4-Me
X
Trends such as this
are found for a very
wide range of
aromatic ionising
functionalities. This
allows prediction of
the pKa of molecules
before they are even
made!
Lipophilicity
Lipophilicity (‘fat-liking’) is the most important physical property of a drug
in relation to its absorption, distribution, potency, and elimination.
Lipophilicity is often an important factor in all of the following, which
include both biological and physicochemical properties:
Solubility
Absorption
Plasma protein binding
Metabolic clearance
Volume of distribution
Enzyme / receptor binding
Biliary and renal clearance
CNS penetration
Storage in tissues
Bioavailability
Toxicity
The hydrophobic effect
Molecular interactions – why don’t oil and water mix?
H
H
H
O
H
O
O
H
H H
H
H
O
H
H H
H
O
O
H
H
H
O
H
O
O
O
O
H
H
H
H
H
H
H
H
O
H
H
H
H
H
H
H
O
H
H
H
H
H
O
H
H
H
This is entropy driven (remember δG = δH – TδS). Hydrophobic
molecules are encouraged to associate with each other in water.
Placing a non-polar surface into water disturbs network of water-water
hydrogen bonds. This causes a reorientation of the network of hydrogen
bonds to give fewer, but stronger, water-water H-bonds close to the nonpolar surface.
Water molecules close to a non-polar surface consequently exhibit
much greater orientational ordering and hence lower entropy than bulk
water.
The hydrophobic effect
This principle also applies to the physical properties of drug molecules.
If a compound is too lipophilic, it may
be insoluble in aqueous media (e.g. gastrointestinal fluid or blood)
bind too strongly to plasma proteins and therefore the free blood
concentration will be too low to produce the desired effect
distribute into lipid bilayers and be unable to reach the inside of the cell
Conversely, if the compound is too polar, it may not be absorbed through
the gut wall due to lack of membrane solubility.
So it is important that the lipophilicity of a potential drug molecule is correct.
How can we measure this?
Partition coefficients
P
Xaqueous
Xoctanol
Partition coefficient P (usually expressed as log10P or logP) is defined as:
P=
[X]octanol
[X]aqueous
P is a measure of the relative affinity of a molecule for the lipid and aqueous
phases in the absence of ionisation.
1-Octanol is the most frequently used lipid phase in pharmaceutical
research. This is because:
It has a polar and non polar region (like a membrane phospholipid)
Po/w is fairly easy to measure
Po/w often correlates well with many biological properties
It can be predicted fairly accurately using computational models
Calculation of logP
LogP for a molecule can be calculated from a sum of fragmental
or atom-based terms plus various corrections.
logP = S fragments + S corrections
H
Branch
H
C
O
H
H
H
C
H
C
C
C H
H
C H
C
C
N
H H
C
H
C
H
H
H
clogP for windows output
C
H C
C
N
C
C
O
H
C
C
Phenylbutazone
C
H
H
C
H
C: 3.16 M: 3.16 PHENYLBUTAZONE
Class
| Type | Log(P) Contribution Description
Value
FRAGMENT | # 1 | 3,5-pyrazolidinedione
-3.240
ISOLATING |CARBON| 5 Aliphatic isolating carbon(s)
0.975
ISOLATING |CARBON| 12 Aromatic isolating carbon(s)
1.560
EXFRAGMENT|BRANCH| 1 chain and 0 cluster branch(es) -0.130
EXFRAGMENT|HYDROG| 20 H(s) on isolating carbons
4.540
EXFRAGMENT|BONDS | 3 chain and 2 alicyclic (net)
-0.540
RESULT
| 2.11 |All fragments measured
clogP 3.165
Blood clot preventing activity
of salicylic acids
O
OH
9
OH
8.5
pIC50
R1
R2
8
7.5
O
OH
O
7
O
6.5
2
3
4
logP
5
6
Aspirin
What else does logP affect?
logP
Binding to
enzyme /
receptor
Aqueous
solubility
Binding to
P450
metabolising
enzymes
So log P needs to be optimised
Absorption
through
membrane
Binding to
blood / tissue
proteins –
less drug free
to act
Binding to
hERG heart
ion channel cardiotoxicity
risk
Distribution coefficients
If a compound can ionise then the observed partitioning between water and
octanol will be pH dependent.
octanol phase
[un-ionised]octanol
insignificant
P
aqueous phase
[un-ionised]aq
For an acidic compound: HAaq
D=
[ionised]aq
H+aq+ A-aq
[HA]octanol
[HA]aq + [A-]aq
For a basic compound: BH+aq
D=
Ka
[B]octanol
[BH+]aq + [B]aq
H+aq+ Baq
Distribution
coefficient D (usually
expressed as logD)
is the effective
lipophilicity of a
compound at a given
pH, and is a function
of both the
lipophilicity of the
un-ionised
compound and the
degree of ionisation.
Relationship between logD, logP and pH for
an acidic drug
O
logP=4.25
O
OH
5
50% neutral
4
N
10%
O
3
logD
1%
2
Cl
0.1%
1
Indomethacin
0.01%
0
0.001% neutral
-1
-2
2
3
4
5
6
7
8
9
10
pH
For singly ionising acids in general:
pKa=4.50
logD = logP - log[1 + 10(pH-pKa)]
pH - Distribution behaviour of bases
Cl
O
4
O
O
3
N
H
Cl
O
2
O
O
N
H
NH2
O
0
H
N
NH3+
-1
CN
N
N
-2
H
N
-3
N
S
S
N
H
N
H
N
H
-4
4
5
6
7
N
H
Cimetidine
pKa=6.8
CN
NH+
3
Amlodipine
pKa=9.3
O
O
1
logD
O
8
9
10
11
pH
For singly ionising bases in general:
logD = logP - log[1 + 10(pKa-pH)]
pH - Distribution behaviour of amphoteric
compounds
OH
pKa2 = 9.8
pKa1 = 4.4
0.5
NH2
0
logD
-0.5
O
-1
OH
-1.5
NH2
-2
NH3+
-2.5
2
3
4
5
6
7
pH
8
9
10
11
12
How can lipophilicity be altered?
R1
O
O
e.g. Monocarboxylate transporter 1 blockers
N
R2
N
X
N
O
OH
R1
N
N
OH
OH
N
N
OH
N
R2
Ar
OH
N
OH
N
O
OH
S
O
F
O
CF3
X
Ar
N
logD
1.7
N
2.0
N
1.2
N
2.9
2.2
3.2
How can lipophilicity be altered?
R1
O
O
e.g. Monocarboxylate transporter 1 blockers
N
R2
N
X
N
O
OH
R1
N
N
OH
OH
N
N
OH
N
R2
Ar
OH
N
OH
N
O
OH
S
O
F
O
CF3
X
Ar
N
logD
1.7
N
2.0
N
1.2
N
2.9
2.2
3.2
Hydrogen bonding
Intermolecular hydrogen bonds are virtually non-existent between small
molecules in water. To form a hydrogen bond between a donor and
acceptor group, both the donor and the acceptor must first break their
hydrogen bonds to surrounding water molecules
+
A H OH2
+
A H B
B HOH
HOH OH2
The position of this equilibrium depends on the relative energies of the
species on either side, and not just the energy of the donor-acceptor
complex
Intramolecular hydrogen bonds are more readily formed in water - they are
entropically more favourable.
O
O
O H
O
O
+
+
O
-H
-
pKa1=1.91
O
H
O
OH
-H
O
HO2C
+
-H
CO2H
O
HO2C
pKa1=3.03
O
pKa2=6.33
+
-H
CO2-
CO2-
pKa2=4.54
CO2-
Hydrogen bonding and bioavailability
Remember! Most oral drugs are absorbed through the gut wall by
transcellular absorption.
H
O
O
H
O
H
H
H
N
O
H
N
H
H
H
O
O
O
H
O
H
O
H
H
H
O H
O
H
O
H
O
+
N
H
O
H
H
H
H O H
H
H
O
H
H
N
H
O
N
O
H
O
N
H
H
H
De-solvation and formation of a neutral molecule is unfavourable if the
compound forms many hydrogen or ionic bonds with water.
So, as a good rule of thumb, you don’t want too many hydrogen bond
donors or acceptors, otherwise the drug won’t get from the gut into the
blood.
There are some exceptions to this – sugars, for example, but these
have special transport mechanisms.
Molecular size
Molecular size is one of the most important factors affecting
biological activity, but it’s also one of the most difficult to
measure.
There are various ways of investigating the molecular size,
including measurement of:
Molecular weight (most important)
Electron density
Polar surface area
Van der Waals surface
Molar refractivity
25
Molecular weight
frequency %
20
15
10
Plot of frequency of
occurrence against molecular
weight for 594 marketed oral
drugs
5
10
015
0
15
020
0
20
025
0
25
030
0
30
035
0
35
040
0
40
045
0
45
050
0
50
055
0
55
060
0
60
065
0
65
070
0
70
075
0
75
080
0
80
085
0
85
090
0
90
095
0
95
010
00
0
Molecular Weight
Most oral drugs have molecular weight < 500
Number of rotatable bonds
A rotatable bond is defined as any single non-ring bond,
attached to a non-terminal, non-hydrogen atom. Amide C-N
bonds are not counted because of their high barrier to rotation.
OH
O
O
No. of rotatable
bonds
H
N
Atenolol
H2N
OH
O
H
N
Propranolol
Number of rotatable bonds
A rotatable bond is defined as any single non-ring bond,
attached to a non-terminal, non-hydrogen atom. Amide C-N
bonds are not counted because of their high barrier to rotation.
OH
O
O
No. of rotatable
bonds
H
N
Bioavailability
Atenolol
8
50%
Propranolol
6
90%
H2N
OH
O
H
N
The number of rotatable bonds influences, in particular,
bioavailability and binding potency. Why should this be so?
Number of rotatable bonds
Remember δG = δH – TδS ! A molecule will have to adopt a fixed
conformation to bind, and to pass through a membrane. This involves a
loss in entropy, so if the molecule is more rigid to start with, less entropy
is lost. But beware!
H
H H
R
H
R
H H
H
H
H
R
H
H
R
R
H
Any, or none, of these could be the active conformation!
70
60
50
Percentage of 40
compounds
with F >20% 30
20
MW 0-499
MW 500+
10
0
# Rot 0-7
# Rot 8-10
# Rot 11+
Bulk physical properties
When a compound is nearing nomination for entry
to clinical trials, we need to look at:
Solubility, including in human intestinal fluid
Hygroscopicity, i.e. how readily a compound
absorbs water from the atmosphere
Crystalline forms – may have different properties
Chemical stability (not a physical property! Look
at stability to pH, temperature, water, air, etc)
How can these be altered?
Different counter ion or salt
Different method of crystallisation
This seems like a lot to remember!
There are various guidelines to help, the most wellknown of which is the Lipinski Rule of Five
molecular weight < 500
logP < 5
< 5 H-bond donors (sum of NH and OH)
< 10 H-bond acceptors (sum of N and O)
An additional rule was proposed by Veber
< 10 rotatable bonds
Otherwise absorption and bioavailability are likely to
be poor. NB This is for oral drugs only.
The Drug Design Conundrum
The conundrum is that while pharmacokinetic properties improve by
modulating bulk properties, potency also depends on these – particularly
lipophilicity. There are then three approaches that could be adopted.
Potency
New receptor interaction
to increase potency and modulate
bulk properties
Find a substitution position not affecting
potency where bulk properties can be
modulated for good DMPK
Trade potency for
DMPK improvements
dose to man focus
logD/Clearance/CYP inhibition